Structural response of different Lewis number premixed flames interacting with a toroidal vortex

Structural response of different Lewis number premixed flames interacting with a toroidal vortex

Simultaneous measurements of temperature, CH* and OH* chemiluminescent species are carried out to explore the impact of stretch rate and curvature on the structure of premixed flames. The configuration of an initially flat premixed flame interacting with a toroidal vortex is selected for the present...

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Bibliographic Details
Published in:Proceedings of the Combustion Institute Vol. 37; no. 2; pp. 1911 - 1918
Main Authors: Bariki, Chaimae, Halter, Fabien, Thiesset, Fabien, Chauveau, Christian, Gökalp, Iskender, Teav, Ketana, Kheirkhah, Sina, Steinberg, Adam M.
Format: Journal Article
Language:English
Published: Elsevier Inc 2019
Elsevier
Subjects:
Chemiluminescence
Curvature/stretch effects
Engineering Sciences
Flame front thinning/thickening
Flame–vortex interaction
Laminar premixed flames
Reactive fluid environment
Flame front thinning/thickening
Chemiluminescence
Curvature/stretch effects
Laminar premixed flames
Flame–vortex interaction
Flame-vortex interaction
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Summary:Simultaneous measurements of temperature, CH* and OH* chemiluminescent species are carried out to explore the impact of stretch rate and curvature on the structure of premixed flames. The configuration of an initially flat premixed flame interacting with a toroidal vortex is selected for the present study and reasons for this choice are discussed. Lewis number effects are assessed by comparing methane and propane flames. It is emphasized that the flame structure experiences very strong variations. In particular, the flame is shrunk (broadened) in the initial (final) period of the interaction with the vortex where strain rate (curvature) contribution of the stretch rate is predominant. By further analysing independently the thickness of the preheat and reaction zones, it is shown that for propane flames, not only the former but also the latter is significantly altered in zones where the flame curvature is negative. Changes in the reaction zone properties are further emphasized using CH* and OH* radicals. It is demonstrated that higher thermal diffusivity plays a significant role around curved regions, in which the enhanced diffusion of heat leads to a strong increase of CH* compared to OH* intensity. As an overall conclusion, this study suggests that it would be interesting to reassess the internal flame structure at lower and moderate Karlovitz numbers since changes might appear for a moderate vortex intensity with typical size much larger than the flame thickness.
ISSN:1540-7489
1873-2704
1540-7489
DOI:10.1016/j.proci.2018.06.114